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Main Authors: Borde, Haitz Sáez de Ocáriz, Innocenzi, Pietro, Savarino, Flavio, Popescu, Andrei Cristian, Papageorgiou, Pantelis
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.28791
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author Borde, Haitz Sáez de Ocáriz
Innocenzi, Pietro
Savarino, Flavio
Popescu, Andrei Cristian
Papageorgiou, Pantelis
author_facet Borde, Haitz Sáez de Ocáriz
Innocenzi, Pietro
Savarino, Flavio
Popescu, Andrei Cristian
Papageorgiou, Pantelis
contents We develop a 3D aerothermodynamic simulator for the Orion reentry capsule at hypersonic speeds, a timely case study given its role in upcoming lunar missions. The large computational meshes required for these scenarios make traditional computational fluid dynamics impractical for full-mission performance prediction and control. In this work, we propose physics-enhanced 3D neural fields for predicting steady hypersonic flow around aerodynamic bodies. The model maps spatial coordinates and angle of attack to pressure, temperature, and velocity components. We enhance the base model with Fourier positional feature mappings, which allow it to capture the sharp discontinuities typical of hypersonic flows, and further constrain the solution by imposing no-slip and isothermal wall conditions. We compare our proposed approach to other surrogate alternatives, such as graph neural networks, and demonstrate its superior performance in capturing the steep gradients ubiquitous in this regime. Our formulation yields a continuous and computationally efficient aerothermodynamic surrogate that supports rapid exploration of operating conditions based on angle of attack variation under realistic flight profiles. While we focus on Orion, the proposed framework provides a general methodology for data-driven simulation in 3D hypersonic aerothermodynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2603_28791
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning 3D Hypersonic Flow with Physics-Enhanced Neural Fields: A Case Study on the Orion Reentry Capsule
Borde, Haitz Sáez de Ocáriz
Innocenzi, Pietro
Savarino, Flavio
Popescu, Andrei Cristian
Papageorgiou, Pantelis
Fluid Dynamics
We develop a 3D aerothermodynamic simulator for the Orion reentry capsule at hypersonic speeds, a timely case study given its role in upcoming lunar missions. The large computational meshes required for these scenarios make traditional computational fluid dynamics impractical for full-mission performance prediction and control. In this work, we propose physics-enhanced 3D neural fields for predicting steady hypersonic flow around aerodynamic bodies. The model maps spatial coordinates and angle of attack to pressure, temperature, and velocity components. We enhance the base model with Fourier positional feature mappings, which allow it to capture the sharp discontinuities typical of hypersonic flows, and further constrain the solution by imposing no-slip and isothermal wall conditions. We compare our proposed approach to other surrogate alternatives, such as graph neural networks, and demonstrate its superior performance in capturing the steep gradients ubiquitous in this regime. Our formulation yields a continuous and computationally efficient aerothermodynamic surrogate that supports rapid exploration of operating conditions based on angle of attack variation under realistic flight profiles. While we focus on Orion, the proposed framework provides a general methodology for data-driven simulation in 3D hypersonic aerothermodynamics.
title Learning 3D Hypersonic Flow with Physics-Enhanced Neural Fields: A Case Study on the Orion Reentry Capsule
topic Fluid Dynamics
url https://arxiv.org/abs/2603.28791